Your search keyword '"Thalmayer Angelika"' showing total 7 results

1. How the Magnetization Angle of a Linear Halbach Array Influences Particle Steering in Magnetic Drug Targeting—A Systematic Evaluation and Optimization.

Author

Thalmayer, Angelika S., Götz, Kilian, and Fischer, Georg

Subjects

*MAGNETIC particles, *TARGETED drug delivery, *BEAM steering, *MAGNETIZATION, *MAGNETIC flux density, *MAGNETISM

Abstract

The main challenge in magnetic drug targeting lies in steering the magnetic particles, especially in deeper body layers. For this purpose, linear Halbach arrays are currently in focus. However, to the best of the authors' knowledge, the impact of the magnetization angle between two neighboring magnets in Halbach arrays has not been investigated for particle steering so far. Therefore, in this paper, a systematic numerical parameter study of varying the magnetization angle of linear Halbach arrays is conducted. This is completed by undertaking a typical magnetic drug targeting scenario, where magnetic particles have to be steered in an optimized manner. This includes the calculation of the magnetic flux density, its gradient, the total magnetic energy, and the resulting magnetic force based on a fitting function for the different Halbach constellations in the context of examining their potential for predicting the particle distribution. In general, increased magnetization angles result in an increased effective range of the magnetic force. However, as there is a trade-off between a weak force on the weak side of the array and a simple manufacturing process, a magnetization angle of 90 ∘ is recommended. For evaluating the steering performance, a numerical or experimental evaluation of the particle distribution is mandatory. [ABSTRACT FROM AUTHOR]

Published

2024

2. Tracking the Traveled Distance of Capsule Endoscopes along a Gastrointestinal-Tract Model Using Differential Static Magnetic Localization.

Author

Zeising, Samuel, Chen, Lu, Thalmayer, Angelika, Lübke, Maximilian, Fischer, Georg, and Kirchner, Jens

Subjects

ENDOSCOPES, PERMANENT magnets, GASTROINTESTINAL system, CAPSULE endoscopy, MAGNETS

Abstract

The traveled distance and orientation of capsule endoscopes for each video frame are not available in commercial systems, but they would be highly relevant for physicians. Furthermore, scientific approaches lack precisely tracking the capsules along curved trajectories within the typical gastrointestinal tract. Recently, we showed that the differential static magnetic localisation method is suitable for the precise absolute localisation of permanent magnets assumed to be integrated into capsule endoscopes. Thus, in the present study, the differential method was employed to track permanent magnets in terms of traveled distance and orientation along a length trajectory of 487.5 mm, representing a model of the winding gastrointestinal tract. Permanent magnets with a diameter of 10 mm and different lengths were used to find a lower boundary for magnet size. Results reveal that the mean relative distance and orientation errors did not exceed 4.3 ± 3.3%, and 2 ± 0.6 ∘ , respectively, when the magnet length was at least 5 mm. Thus, a 5 mm long magnet would be a good compromise between achievable tracking accuracy and magnet volume, which are essential for integration into small commercial capsules. Overall, the proposed tracking accuracy was better than that of the state of the art within a region covering the typical gastrointestinal-tract size. [ABSTRACT FROM AUTHOR]

Published

2022

3. Investigation of Particle Steering for Different Cylindrical Permanent Magnets in Magnetic Drug Targeting

Author

Thalmayer, Angelika, primary, Zeising, Samuel, additional, Fischer, Georg, additional, and Kirchner, Jens, additional

Published

2020

4. Performance Optimization of a Differential Method for Localization of Capsule Endoscopes

Author

Zeising, Samuel, primary, Ararat, Kivanc, additional, Thalmayer, Angelika, additional, Anzai, Daisuke, additional, Fischer, Georg, additional, and Kirchner, Jens, additional

Published

2020

5. Commercial and Scientific Solutions for Blood Glucose Monitoring—A Review.

Author

Xue, Yirui, Thalmayer, Angelika S., Zeising, Samuel, Fischer, Georg, and Lübke, Maximilian

Subjects

*BLOOD sugar monitoring, *BLOOD sugar monitors, *HYPERGLYCEMIA, *BLOOD sugar, *INCURABLE diseases, *HYPOGLYCEMIA

Abstract

Diabetes is a chronic and, according to the state of the art, an incurable disease. Therefore, to treat diabetes, regular blood glucose monitoring is crucial since it is mandatory to mitigate the risk and incidence of hyperglycemia and hypoglycemia. Nowadays, it is common to use blood glucose meters or continuous glucose monitoring via stinging the skin, which is classified as invasive monitoring. In recent decades, non-invasive monitoring has been regarded as a dominant research field. In this paper, electrochemical and electromagnetic non-invasive blood glucose monitoring approaches will be discussed. Thereby, scientific sensor systems are compared to commercial devices by validating the sensor principle and investigating their performance utilizing the Clarke error grid. Additionally, the opportunities to enhance the overall accuracy and stability of non-invasive glucose sensing and even predict blood glucose development to avoid hyperglycemia and hypoglycemia using post-processing and sensor fusion are presented. Overall, the scientific approaches show a comparable accuracy in the Clarke error grid to that of the commercial ones. However, they are in different stages of development and, therefore, need improvement regarding parameter optimization, temperature dependency, or testing with blood under real conditions. Moreover, the size of scientific sensing solutions must be further reduced for a wearable monitoring system. [ABSTRACT FROM AUTHOR]

Published

2022

6. Systematic Performance Evaluation of a Novel Optimized Differential Localization Method for Capsule Endoscopes †.

Author

Zeising, Samuel, Ararat, Kivanc, Thalmayer, Angelika, Anzai, Daisuke, Fischer, Georg, Kirchner, Jens, and Mariani, Stefano

Subjects

ENDOSCOPES, SENSOR placement, FERROMAGNETIC materials, CAPSULE endoscopy, ACTINIC flux

Abstract

Capsule endoscopy is a well-established diagnostic tool for the gastrointestinal tract. However, the reliable tracking of capsule endoscopes needs further investigation. Recently, the static magnetic differential method for the localization of capsule endoscopes has shown promising results. This method was experimentally validated by investigating the difference in the measured values of the geomagnetic flux density of a representative sensor pair. In the measurements, it was revealed that misalignment of the sensors and ferromagnetic material near the sensor pair had the most significant impact on the differential approach. Besides, a systematical simulation-based study was conducted. Herein, the position and alignment of all sensors of the localization system were randomly varied. Furthermore, root-mean-squared noise was added to the sensor measurements, and the influence of nearby ferromagnetic material was evaluated. Subsequently, non-idealities were applied simultaneously on the proposed localization system, and the entire system was rotated. The proposed method was significantly better than state-of-the-art geomagnetic compensation methods for the localization of capsule endoscopes with mean position and orientation errors of approximately 2 mm and 1°, respectively. [ABSTRACT FROM AUTHOR]

Published

2021

7. A Robust and Real-Time Capable Envelope-Based Algorithm for Heart Sound Classification: Validation under Different Physiological Conditions.

Author

Thalmayer, Angelika, Zeising, Samuel, Fischer, Georg, and Kirchner, Jens

Subjects

*HEART sounds, *CLASSIFICATION algorithms, *FOURIER transforms, *ALGORITHMS, *CLASSIFICATION, *HEART beat

Abstract

This paper proposes a robust and real-time capable algorithm for classification of the first and second heart sounds. The classification algorithm is based on the evaluation of the envelope curve of the phonocardiogram. For the evaluation, in contrast to other studies, measurements on 12 probands were conducted in different physiological conditions. Moreover, for each measurement the auscultation point, posture and physical stress were varied. The proposed envelope-based algorithm is tested with two different methods for envelope curve extraction: the Hilbert transform and the short-time Fourier transform. The performance of the classification of the first heart sounds is evaluated by using a reference electrocardiogram. Overall, by using the Hilbert transform, the algorithm has a better performance regarding the F1-score and computational effort. The proposed algorithm achieves for the S1 classification an F1-score up to 95.7% and in average 90.5%. The algorithm is robust against the age, BMI, posture, heart rate and auscultation point (except measurements on the back) of the subjects. [ABSTRACT FROM AUTHOR]

Published

2020